Optimal operation of a multi-energy system considering renewable energy sources stochasticity and impacts of electric vehicles

Electrical, heating and cooling energy demands of the end users are increasing day by day. For the sake of using fewer fossil fuels, decreasing the energy costs and gas emissions as well as increasing the efficiency and flexibility of the traditional energy systems, multi-energy systems (MESs) have...

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Bibliographic Details
Published in:Energy (Oxford) 2019-11, Vol.186, p.115841, Article 115841
Main Authors: Ata, Mustafa, Erenoğlu, Ayşe Kübra, Şengör, İbrahim, Erdinç, Ozan, Taşcıkaraoğlu, Akın, Catalão, João P.S.
Format: Article
Language:English
Subjects:
Alternative energy sources
Cogeneration
Comparative studies
Computer simulation
Costs
Electric vehicles
Electrical loads
Electricity
End users
Energy
Energy costs
Energy resources
Energy sources
Flexibility
Fossil fuels
Heat exchangers
Heat pumps
Heating and cooling
Integer programming
Linear programming
Mixed integer
Multi energy systems
Operating costs
Photovoltaic cells
Photovoltaics
Radiation
Real gases
Reduction
Renewable energy sources
Stochasticity
Time of use electricity pricing
Wind
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Summary:Electrical, heating and cooling energy demands of the end users are increasing day by day. For the sake of using fewer fossil fuels, decreasing the energy costs and gas emissions as well as increasing the efficiency and flexibility of the traditional energy systems, multi-energy systems (MESs) have begun to be used. In this study, a MES structure which also includes renewable-based generation units as suppliers together with combined heating and power (CHP) and heat pumps (HPs) is presented. The proposed MES structure is modelled as a mixed integer linear programming (MILP) problem with the objective of minimizing total gas and electricity costs in daily operation. Furthermore, electric vehicles (EVs) as a new type of electrical load with inherently different characteristics are evaluated considering different end-user types as residential and commercial together with the capability of offering operational flexibility. In order to tackle with the intermittent structure of the renewable energy sources, a scenario oriented stochastic programming concept is taken into account by addressing real radiation, temperature, and wind data. Moreover, actual time-of-use (TOU) tariffs for electricity prices along with the real gas prices are evaluated. The simulation results of the devised model are given for different case studies and the effectiveness of the system is demonstrated via a comparative study. As a result, it is found that the operational costs are decreased nearly 5.49% by integrating only photovoltaic (PV) production according to the case which has no additional sources. Also, a substantial reduction of 13.45% is achieved by considering both PV and wind generation. Moreover, the flexibility is increased with taking EVs into account on the demand side and this leads to a cost reduction of 8.81% even if EVs are integrated to the system as an extra load. •In this study, a Multi Energy System (MES) structure is presented.•The MES structure is modelled as a mixed integer linear programming problem.•Electric vehicles are evaluated considering different user types.•A scenario oriented stochastic programming is taken into account.•Time-of-use tariff for electricity prices along with real gas prices are evaluated.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2019.07.171